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In yeast, inosine is found at the first position of the anticodon (position 34) of seven different isoacceptor tRNA species, while in Escherichia coli it is present only in tRNAArg. The corresponding tRNA genes all have adenosine at position 34. Using as substrates in vitro T7-runoff transcripts of 31 plasmids carrying each natural of synthetic tRNA gene harbouring an anticodon with adenosine 34, we have characterised a yeast enzyme that catalyses the conversion of adenosine 34 to inosine 34. The homologous E. coli enzyme modifies adenosine 34 only in tRNAs with an arginine anticodon ACG. The base conversion occurs by a hydrolytic deamination-type reaction. This was determined by reversed phase high-pressure liquid chromatography/electrospray mass spectrometry analysis of the reaction product after in vitro modification in [18O]water. This newly characterised tRNA:adenosine 34 deaminase was partially purified from yeast. It has a molecular mass of approximately 75 kDa, and it does not require any cofactor, except magnesium ions, to deaminate adenosine 34 efficiently in tRNA. The observed dependence of the enzymatic reaction on magnesium ions probably reflects the need for a correct tRNA architecture. Enzymatic recognition of tRNA does not depend on the presence of any "identify" nucleoside other than adenosine 34. Likewise, the presence of pseudouridine 32 or 1-methyl-guanosine 37 in the anticodon loop does not interfere with inosine 34 biosynthesis. However, the efficacy of adenosine 34 to inosine 34 conversion depends on the nucleotide sequence of the anticodon loop and its proximal stem, the best tRNA substrates being those with a purine at position 35. Mutations that affect the size of the anticodon loop or one of several three-dimensional base-pairs abolish the capacity of the tRNA to be substrate for the yeast tRNA:adenosine 34 deaminase. Evidently, the activity of yeast tRNA:adenosine 34 deaminase depends more on the global structural feature (conformational stability/flexibility) of the L-shaped tRNA substrates than on the identity of any particular nucleotide other than adenosine 34. An apparent K(m) of 2.3 nM for its natural substrate tRNASer (anticodon AGA) was measured. Altogether, these results suggest that a single enzyme can account for the presence of inosine 34 in all seven cytoplasmic A34-containing precursor tRNAs in yeast.
J Mol Biol 1996 Oct 04
PMID:Mechanism, specificity and general properties of the yeast enzyme catalysing the formation of inosine 34 in the anticodon of transfer RNA. 889 55

The Arabidopsis G alpha subunit, GP alpha1, was expressed within Escherichia coli by co-transformation with the expression vector and the dnaY gene which encodes tRNA(Arg)(AGA/AGG) Isolation of the recombinant GP alpha1 in a highly pure form could be achieved by a combination of anion exchange and dye affinity chromatography or by a single step affinity procedure via chromatography on 4-amino-anilido-GTP agarose. The recombinant protein yielded by both procedures was highly active and bound GTPgammaS with an apparent Kd in the nM range. GTPgammaS binding was stimulated two-fold in the presence of Zn2+ compared with that in the presence of Mg2+, Mn2+ or Ca2+.
Plant Mol Biol 1997 Mar
PMID:Expression of the Arabidopsis G-protein GP alpha1: purification and characterisation of the recombinant protein. 913 63

We have cloned the mitochondrial DNA fragment extending from tRNA-Leu to the cytochrome oxidase subunit 1 (COI) genes of Branchiostoma lanceolatum, Myxine glutinosa, Lampetra fluviatilis, and Scyliorhinus caniculus and have determined their respective gene sequences and organization. In all four species, this region contains the ND1 and ND2 genes and the genes coding eight tRNAs, namely, tRNA-Ile, -Gln, -Met, -Trp, -Ala, -Asn, -Cys, and -Tyr. The gene order is the same in the hagfish, lamprey and dogfish. In the lancelet, the location of the tRNA genes is slightly different. The mitochondrial code of Myxine, Lampetra, and Scyliorhinus is identical to that of vertebrates. The code used by the lancelet is the same with the exception of AGA (a stop codon in vertebrates), which codes for glycine in the lancelet. From the comparison of the four maps with already published ones for other species, we propose that the main features of the craniate mtDNA between the ND1 and COI genes were established in the common ancestor to cephalochordates and vertebrates more than 400 MYA. The origin of replication of the light-strand (Ori-L), usually located between the tRNA-Asn and tRNA-Cys genes in vertebrates, was not found in the lancelet, hagfish, or lamprey (Lampetra). In contrast, it was found in the dogfish. Thus the position of Ori-L was established for the first time in the common ancestor to the Chondrichthyes and Osteichthyes and remained present in all later-emerging vertebrates.
Mol Biol Evol 1997 Aug
PMID:The main features of the craniate mitochondrial DNA between the ND1 and the COI genes were established in the common ancestor with the lancelet. 925 18

Protein import into mitochondria involves several components of the mitochondrial outer and inner membranes as well as molecular chaperones located inside mitochondria. Here, we have investigated the effect of sulfhydryl group reagents on import of the in vitro transcribed/translated precursor of the F1 beta subunit of the ATP synthase (pF1 beta) into Solanum tuberosum mitochondria. We have used a reducing agent, dithiothreitol (DTT), a membrane-permeant alkylating agent, N-ethylmaleimide (NEM), a non-permeant alkylating agent, 3-(N-maleimidopropionyl)biocytin (MPB), an SH-group specific agent and cross-linker 5,5'-dithiobis-(2-nitrobenzoic acid) (DTNB) as well as an oxidizing cross-linker, copper sulfate. DTT stimulated the mitochondrial protein import, whereas NEM, MPB, DTNB and Cu2+ were inhibitory. Inhibition by Cu2+ could be reversed by addition of DTT. The efficiency of inhibition was higher in energized mitochondrial than in non-energized. We have dissected the effect of the SH-group reagents on binding, unfolding and transport of the precursor into mitochondria. Our results demonstrated that the inhibitory effect of NEM, DTNB and Cu2+ on the efficiency of import was not due to the interaction of the SH-group reagents with import receptors. Modification of pF1 beta with NEM prior to the import resulted in stimulation of import, whereas DTNB and Cu2+ were inhibitory. NEM, MPB, DTNB and Cu2+ inhibited import of the NEM-modified pF1 beta into intact mitochondria. Import of pF1 beta through a receptor-independent bypass-route as well as import into mitoplasts were sensitive to DTT, NEM, MPB, DTNB and Cu2+ in a similar manner as import into mitochondria. As MPB does not cross the inner membrane, these results indicated that redox and conformational status of SH groups located on the outer surface of the inner mitochondrial membrane were essential for protein import.
Plant Mol Biol 1997 Dec
PMID:Mitochondrial protein import: modification of sulfhydryl groups of the inner mitochondrial membrane import machinery in Solanum tuberosum inhibits protein import. 942 1

The nucleotide sequences of two segments of 6,737 ntp and 258 nto of the 18.4-kb circular mitochondrial (mt) DNA molecule of the soft coral Sarcophyton glaucum (phylum Cnidaria, class Anthozoa, subclass Octocorallia, order Alcyonacea) have been determined. The larger segment contains the 3' 191 ntp of the gene for subunit 1 of the respiratory chain NADH dehydrogenase (ND1), complete genes for cytochrome b (Cyt b), ND6, ND3, ND4L, and a bacterial MutS homologue (MSH), and the 5' terminal 1,124 ntp of the gene for the large subunit rRNA (1-rRNA). These genes are arranged in the order given and all are transcribed from the same strand of the molecule. The smaller segment contains the 3' terminal 134 ntp of the ND4 gene and a complete tRNA(f-Met) gene, and these genes are transcribed in opposite directions. As in the hexacorallian anthozoan, Metridium senile, the mt-genetic code of S. glaucum is near standard: that is, in contrast to the situation in mt-genetic codes of other invertebrate phyla, AGA and AGG specify arginine, and ATA specifies isoleucine. However, as appears to be universal for metazoan mt-genetic codes, TGA specifies tryptophan rather than termination. Also, as in M. senile the mt-tRNA(f-Met) gene has primary and secondary structural features resembling those of Escherichia coli initiator tRNA, including standard dihydrouridine and T psi C loop sequences, and a mismatched nucleotide pair at the top of the amino-acyl stem. The presence of a mutS gene homologue, which has not been reported to occur in any other known mtDNA, suggests that there is mismatch repair activity in S. glaucum mitochondria. In support of this, phylogenetic analysis of MutS family protein sequences indicates that the S. glaucum mtMSH protein is more closely related to the nuclear DNA-encoded mitochondrial mismatch repair protein (MSH1) of the yeast Saccharomyces cerevisiae than to eukaryotic homologues involved in nuclear function, or to bacterial homologues. Regarding the possible origin of the S. glaucum mtMSH gene, the phylogenetic analysis results, together with comparative base composition considerations, and the absence of an MSH gene in any other known mtDNA best support the hypothesis that S. glaucum mtDNA acquired the mtMSH gene from nuclear DNA early in the evolution of octocorals. The presence of mismatch repair activity in S. glaucum mitochondria might be expected to influence the rate of evolution of this organism's mtDNA.
J Mol Evol 1998 Apr
PMID:Mitochondrial DNA of the coral Sarcophyton glaucum contains a gene for a homologue of bacterial MutS: a possible case of gene transfer from the nucleus to the mitochondrion. 954 36

We have determined the 15,083-nucleotide (nt) sequence of the mitochondrial DNA (mtDNA) of the lancelet Branchiostoma floridae (Chordata: Cephalochordata). As is typical in metazoans, the mtDNA encodes 13 protein, 2 rRNA, and 22 tRNA genes. The gene arrangement differs from the common vertebrate arrangement by only four tRNA gene positions. Three of these are unique to Branchiostoma, but the fourth is in a position that is primitive for chordates. It shares the genetic code variations found in vertebrate mtDNAs except that AGA = serine, a code variation found in many invertebrate phyla but not in vertebrates (the related codon AGG was not found). Branchiostoma mtDNA lacks a vertebrate-like control region; its largest noncoding region (129 nt) is unremarkable in sequence or base composition, and its location between ND5 and tRNAG differs from that usually found in vertebrates. It also lacks a potential hairpin DNA structure like those found in many (though not in all) vertebrates to serve as the second-strand (i.e., L-strand) origin of replication. Perhaps related to this, the sequence corresponding to the DHU arm of tRNAC cannot form a helical stem, a condition found in a few other vertebrate mtDNAs that also lack a canonical L-strand origin of replication. ATG and GTG codons appear to initiate translation in 11 and 2 of the protein-encoding genes, respectively. Protein genes end with complete (TAA or TAG) or incomplete (T or TA) stop codons; the latter are presumably converted to TAA by post-transcriptional polyadenylation.
Mol Biol Evol 1999 Mar
PMID:Complete sequence, gene arrangement, and genetic code of mitochondrial DNA of the cephalochordate Branchiostoma floridae (Amphioxus) 1033 Dec 67

Androgenetic alopecia is the most common form of balding in humans. There is great interest in finding a reliable animal model to study the pathogenesis and treatment of this abnormality. The sump-tailed macaque (Macaca artoides) has been the standard model and appears to be useful homologue. These primates are reasonably good predictors of compound efficacy. Due to reduced size and expense, rodent models have been sought. Testosterone inducible models require more development but offer potential. Xenografts of human skin to immunodeficient mice, notably nude or severe combined immunodeficiency, are small, relatively inexpensive, and easy to work with if a source of human tissue is available. Xenografts to double mutant mice for severe combined immunodeficiency and a number of hormone receptor null mutations offer new refinements to these xenograft models.
Exp Mol Pathol 1999 Oct
PMID:Androgenetic alopecia: in vivo models. 1052 63

A 1230-bp region of the cytochrome c oxidase subunit I (COI) gene of mitochondrial DNA of each of 16 brachiopod species, representing all five living orders, was amplified by polymerase chain reaction and sequenced. Pairwise comparisons of sequence differences plotted against divergence times estimated from the brachiopod fossil record revealed that, although there are considerable variations in the expected substitution rate among different lineages, amino acid substitutions of the COI sequences may largely become saturated in 100 Ma, due mostly to multiple substitutions at the same site. Coinciding with this result, phylogenetic analysis indicated low bootstrap values for nodes corresponding to divergence events that occurred before 100 Ma, suggesting that COI sequences are suitable only for inference of phylogenetic events subsequent to the Mesozoic. Examination of brachiopod codons corresponding to invariant amino acids in the COI of various other animals suggest the nonuniversal codon relationships UGA = Trp, AUA = Met, AAA/G = Lys, and AGA/G = Ser. These are identical to those in mollusks, annelids, and arthropods, consistent with the conclusion that brachiopods are protostomes, as indicated by previous molecular analyses.
Mol Phylogenet Evol 2000 Jun
PMID:Mitochondrial COI sequences of brachiopods: genetic code shared with protostomes and limits of utility for phylogenetic reconstruction. 1086 Jun 43

It is well known that protein synthesis in ribosomes on mRNA requires two kinds of tRNAs: initiation and elongation. The former initiates the process (formylmethionine tRNA in prokaryotes and special methionine tRNA in eukaryotes). The latter participates in the synthesis proper, recognizing the sense codons. The synthesis is assisted by special proteins: initiation, elongation, and termination factors. The termination factors are necessary to recognize stop codons (UAG, UGA, and UAA) and to release the complete protein chain from the elongation tRNA preceding a stop codon. No termination tRNA capable of recognizing stop codons by its anticodon is known. The termination factors are thought to do this. We discovered in the large ribosomal RNA two regions that, like tRNAs, contain the anticodon hairpin, but with triplets complementary to stop codons. By analogy, we called them termination tRNAs (Ter-tRNA1 and Ter-tRNA2), though they transport no amino acids, and suggested them to directly recognize stop codons. The termination factors only condition such a recognition, making it specific and reliable (of course, they fulfill the hydrolysis of the ester bond between the polypeptide and tRNA). A strong argument in favor of our hypothesis came from vertebrate mitochondria. They acquired two new stop codons, AGA and AGG (in the standard code, they are two out of six arginine codons). We revealed that the corresponding anticodons appear in Ter-tRNA1.
Mol Biol (Mosk)
PMID:[Why termination tRNAs have not been found? Because they are hidden in the large ribosomal RNA]. 1152 59

CSTX-9 (68 residues, 7530.9 Da) is one of the most abundant toxic polypeptides in the venom of the wandering spider Cupiennius salei. The amino acid sequence was determined by Edman degradation using reduced and alkylated CSTX-9 and peptides generated by cleavages with endoproteinase Asp-N and trypsin, respectively. Sequence comparison with CSTX-1, the most abundant and the most toxic polypeptide in the crude spider venom, revealed a high degree of similarity (53% identity). By means of limited proteolysis with immobilised trypsin and RP-HPLC, the cystine-containing peptides of CSTX-9 were isolated and the disulphide bridges were assigned by amino acid analysis, Edman degradation and nanospray tandem mass spectrometry. The four disulphide bonds present in CSTX-9 are arranged in the following pattern: 1-4, 2-5, 3-8 and 6-7 (Cys6-Cys21, Cys13-Cys30, Cys20-Cys48, Cys32-Cys46). Sequence comparison of CSTX-1 with CSTX-9 clearly indicates the same disulphide bridge pattern, which is also found in other spider polypeptide toxins, e.g. agatoxins (omega-AGA-IVA, omega-AGA-IVB, mu-AGA-I and mu-AGA-VI) from Agelenopsis aperta, SNX-325 from Segestria florentina and curtatoxins (CT-I, CT-II and CT-III) from Hololena curta. CSTX-1/CSTX-9 belong to the family of ion channel toxins containing the inhibitor cystine knot structural motif. CSTX-9, lacking the lysine-rich C-terminal tail of CSTX-1, exhibits a ninefold lower toxicity to Drosophila melanogaster than CSTX-1. This is in accordance with previous observations of CSTX-2a and CSTX-2b, two truncated forms of CSTX-1 which, like CSTX-9, also lack the C-terminal lysine-rich tail.
Cell Mol Life Sci 2001 Sep
PMID:CSTX-9, a toxic peptide from the spider Cupiennius salei: amino acid sequence, disulphide bridge pattern and comparison with other spider toxins containing the cystine knot structure. 1169 32


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